For the TLDR; crowd, some simple code that hopefully explains what the CompoundValue()
function is trying to do, and which might help in converting it's functionality:
# from: Chapter 12. Past/Future Offset and Prefetch
# https://tlc.thinkorswim.com/center/reference/thinkScript/tutorials/Advanced/Chapter-12---Past-Offset-and-Prefetch
# According to this tutorial, thinkScript uses the highest offset, overriding
# all lower offsets in the script - WOW
declare lower;
# recursive addition using x[1] is overridden by 11 in the plot for
# Average(close, 11) below; SO `x = x[1] + 1` becomes `x = x[11] + 1`
def x = x[1] + 1;
# using CompoundValue, though, we can force the use of the *desired* value
# arguments are:
# - length: the number of bars for this variable's offset (`1` here)
# - "visible data": value to use IF VALUES EXIST for a bar (a calculation here)
# - "historical data": value to use IF NO VALUE EXISTS for a bar (`1` here)
def y = CompoundValue(1, y[1] + 1, 1);
# *plotting* this Average statement will change ALL offsets to 11!
plot Average11 = Average(close, 11);
# `def`ing the offset DOES NOT change other offsets, so no issue here
# (if the `def` setup DID change the offsets, then `x[1]` would
# become `x[14]`, as 14 is higher than 11. However, `x[1]` doesn't change.
def Average14 = Average(close, 14);
plot myline = x;
plot myline2 = y;
# add some labels to tell us what thinkScript calculated
def numBars = HighestAll(BarNumber());
AddLabel(yes, "# Bars on Chart: " + numBars, Color.YELLOW);
AddLabel(yes, "x @ bar 1: " + GetValue(x, numBars), Color.ORANGE);
AddLabel(yes, "x @ bar " + numBars + ": " + x, Color.ORANGE);
AddLabel(yes, "y @ bar 1: " + GetValue(y, numBars), Color.LIGHT_ORANGE);
AddLabel(yes, "y @ bar " + numBars + ": " + y, Color.ORANGE);
Now, some, er, lots of details...
First, a quick note on "offset" values:
thinkScript, like other trading-related languages, uses an internal looping system. This is like a for
loop, iterating through all the "periods" or "bars" on a chart (eg, 1 bar = 1 day on a daily chart; 1 bar = 1 minute on a 1 minute intraday chart, etc). Every line of code in thinkScript is run for each and every bar in the chart or length of time specified in the script.
As noted by the OP, x[1]
represents an offset of one bar before the current bar the loop is processing. x[2]
represents two bars before the current bar, and so on. Additionally, it's possible to offset into the future by using negative numbers: x[-1]
means one bar ahead of the current bar, for example.
These offsets work similarly to the for
loop in C#, except they're backwards: x[0]
in C# would represent the current x
value, as it would in thinkScript; however, moving forward in the loop, x[1]
would be the next value, and x[-1]
wouldn't exist because, well, there is no past value before 0. (In general, of course! One can definitely loop with negative numbers in C#. The point is that positive offset indices in thinkScript represent past bars, while negative offset indices in thinkScript represent future bars - not the case in C#.)
Also important here is the concept of "length": in thinkScript, length
parameters represent the distance you want to go - like the offset, but a range instead of one specific bar. In my example code above, I used the statement plot Average11 = Average(close, 11);
In this case, the 11
parameter represents plotting the close for a period of 11 bars, ie, offsets x[0]
through x[10]
.
Now, to explain the CompoundValue() function's purpose:
The Chapter 12. Past/Future Offset and Prefetch thinkScript tutorial explains that thinkScript actually overrides smaller offset or length values with the highest value in a script. What that means is that if you have two items defined as follows:
def x = x[1] + 1;
plot Average11 = Average(close, 11);
thinkScript will actually override the x[1]
offset with the higher length used in the Average statement - therefore causing x[1]
to become x[11]
!
Yike! That means that the specified offsets, except the highest offset, mean nothing to thinkScript! So, wait a minute - does one have to use all the same offsets for everything, then? No! This is where CompoundValue() comes in...
That same chapter explains that CompoundValue() allows one to specify an offset for a variable that won't be changed, even if a higher offset exists.
The CompoundValue() function, with parameter labels, looks like this:
CompoundValue(length, "visible data", "historical data")
As the OP noted, this isn't really particularly clear. Here's what the parameters represent:
length: the offset number of bars for this variable.
In our example, def x = x[1] + 1
, there is a 1 bar offset, so our statement starts as CompoundValue(length=1, ...)
. If instead, it was a larger offset, say 14 bars, we'd put CompoundValue(length=14, ...)
"visible data": the value or calculation thinkScript should perform if DATA IS AVAILABLE for the current bar.
Again, in our example, we're using a calculation of x[1] + 1
, so CompoundValue(length=1, "visible data"=(x[1] + 1), ...)
. (Parentheses around the equation aren't necessary, but may help with clarity.)
"historical data": the value to use if NO DATA IS AVAILABLE for the current bar.
In our example, if no data is available, we'll use a value of 1
.
Now, in thinkScript, parameter labels aren't required if the arguments are in order and/or defaults are supplied. So, we could write this CompoundValue statement like this without the labels:
def y = CompoundValue(1, y[1] + 1, 1);
or like this with the labels:
def y = CompoundValue(length=1, "visible data"=(y[1] + 1), "historical data"=1);
(Note that parameter names containing spaces have to be surrounded by double quotes. Single-word parameter names don't need the quotes. Also, I've placed parens around the equation just for the sake of clarity; this is not required.)
In summary: CompoundValue(...) is needed to ensure a variable uses the actual desired offset/number of bars in a system (thinkScript) that otherwise overrides the specified offsets with a higher number if present.
If all the offsets in a script are the same, or if one is using a different programming system, then CompoundValue() can simply be broken down into its appropriate calculations or values, eg def x = x[1] + 1
or, alternatively, an if/else
statement that fills in the values desired at whatever bars or conditions are needed.